KR20120059839A - System for collecting and managing rainfall attenuation and rainfall intensity on satellite communications system - Google Patents

Abstract

PURPOSE: A system for collecting and managing rainfall attenuation and intensity data from a satellite communication system is provided to accurately match rainfall attenuation and intensity data if the data is simultaneously generated. CONSTITUTION: A system for collecting and managing rainfall attenuation and intensity data from a satellite communication system includes a satellite transmitter(10), a global positioning system(GPS)(20), at least one data collecting units(100, 200), and a data managing unit(1000). The satellite transmitter transmits satellite beacon signals. The GPS transmits GPS signals. If the satellite beacon signals are received, the data collecting units generate rainfall attenuation data with respect to the received satellite beacon signals and generate rainfall intensity data in the effective path length of the rainfall attenuation. Time information is extracted from the GPS signals and is added to the rainfall attenuation data and the rainfall intensity data. The data managing unit receives and manages the rainfall attenuation data and rainfall intensity data.

Description

System for collecting and managing rainfall attenuation and rainfall intensity data in satellite communication systems {SYSTEM FOR COLLECTING AND MANAGING RAINFALL ATTENUATION AND RAINFALL INTENSITY ON SATELLITE COMMUNICATIONS SYSTEM}

Embodiments of the present invention relate to a system for collecting and managing rainfall attenuation and rainfall intensity data in a satellite communication system.

The satellite beacon signal used in the satellite communication system is a signal transmitted by a satellite transmitter located at an altitude of 36,000 km. This satellite beacon signal is scattered and attenuated by raindrops (or snow) from clouds floating at an altitude of about 4 km. The degree to which the satellite beacon signal is attenuated by raindrops is called rainfall attenuation.

In general, since the attenuation amount of the satellite beacon signal changes according to the size of the raindrop, that is, the rainfall intensity, it is necessary to measure the rainfall intensity while measuring the rainfall attenuation.

Conventionally, rainfall attenuation and rainfall intensity are measured using separate devices, and then rainfall attenuation data and rainfall intensity data are generated, and each device is manipulated by humans to transmit rainfall attenuation data and rainfall intensity to a central processing unit or a management device. It was common to do. In the process, due to human manipulation, no immediate data transfer was possible.

In addition, in countries with many localized heavy rains, such as the Republic of Korea, rainfall intensity should be measured in as many regions as possible to develop rainfall attenuation prediction models. However, it was difficult to measure accurate rainfall attenuation and rainfall intensity in each region because rainfall intensity was measured without considering the effective path length of rainfall attenuation.

In addition, rainfall attenuation data and rainfall intensity data having the same time information may be matched to each other. Each device obtains time information from a general purpose computer for triggering a module included therein, but proper time information cannot be obtained in case of a time error or failure of the general purpose computer. Therefore, the time information in which the rainfall attenuation data and the rainfall intensity data are generated is not accurate and cannot be accurately matched.

Embodiments of the present invention have been made to solve the above-mentioned problems, and an object of the present invention is to measure rainfall attenuation and rainfall intensity in one device, and transmit the rainfall attenuation and rainfall intensity data by transmitting them to a data management device through an Ethernet communication network. It is to provide a system that can automatically manage the transmission in real time.

Another object of the present invention is to provide a system capable of collecting and managing accurate rainfall attenuation and rainfall intensity data by measuring rainfall intensity in a plurality of regions in consideration of the effective path length of rainfall attenuation.

Another object of the present invention is to provide a system capable of accurately matching rainfall attenuation and rainfall intensity data generated at the same time by extracting time information from a GPS signal and adding it to rainfall attenuation and rainfall intensity data. will be.

System for collecting and managing rainfall attenuation and rainfall intensity data according to an embodiment of the present invention for achieving the above object, GPS transmitter for transmitting satellite beacon signal, GPS for transmitting a Global Positioning System (GPS) signal When the satellite beacon signal is received from the satellite transmitter, generates rainfall attenuation data for the received satellite beacon signal, generates rainfall intensity data within an effective path length of the rainfall attenuation, and time information from the GPS signal. At least one data collection device for extracting and adding to the rainfall attenuation data and the rainfall intensity data, and a data management device for receiving and managing the rainfall attenuation data and the rainfall intensity data added with the time information from the data collection device. It includes.

The system for collecting and managing rainfall attenuation and rainfall intensity data according to an embodiment of the present invention transmits the rainfall attenuation and rainfall intensity data to a data management device through an Ethernet communication network in real time, thereby reducing manpower costs and providing fast data transmission. Can be.

In addition, the system for collecting and managing the data may collect and manage accurate rainfall attenuation and rainfall intensity data by measuring rainfall intensity in a plurality of regions in consideration of the effective path length of rainfall attenuation.

In addition, the system for collecting and managing the data extracts time information from the GPS signal and adds it to the rainfall attenuation and rainfall intensity data, thereby accurately matching the rainfall attenuation and rainfall intensity data generated at the same time.

1 is a view showing a system for collecting and managing rainfall attenuation and rainfall intensity data in a satellite communication system according to an embodiment of the present invention.
2 is a block diagram showing the configuration of a data collection device for collecting rainfall attenuation and rainfall intensity data according to an embodiment of the present invention.
3 is a view showing a rainfall attenuation measurement module installed in a plurality of areas according to an embodiment of the present invention.
4 is a flowchart illustrating a method of collecting and managing rainfall attenuation and rainfall intensity data in a satellite communication system according to an exemplary embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. In addition, terms used herein are terms used to properly express preferred embodiments of the present invention, which may vary depending on the intention of a user, an operator, or customs in the field to which the present invention belongs. Therefore, the definitions of the terms should be made based on the contents throughout the specification. Like reference numerals in the drawings denote like elements.

1 is a view showing a system for collecting and managing rainfall attenuation and rainfall intensity data (hereinafter, referred to as a 'system') in a satellite communication system according to an embodiment of the present invention.

Referring to FIG. 1, the system includes a satellite transmitter 10, a global positioning system (GPS) 20, a first data collection device 100, and a data management device 1000. In FIG. 1, the system may include at least one first data collection device 100 that measures rainfall attenuation and rainfall intensity to collect rainfall attenuation data and rainfall intensity data. Specifically, the first and second data collection devices 100 and 200 may be installed in different regions in consideration of the effective path length of the rainfall attenuation.

In FIG. 1, only the region in which the first data collecting device 100 and the second data collecting device 200 are installed is different but the operation and configuration thereof are the same. Therefore, in FIG. 1, an operation and a configuration will be described with the first data collection device 100 as a representative.

In addition, although FIG. 1 illustrates a system including the first and second data collection devices 100 and 200, the device may be further installed in a plurality of regions within the effective path length of the rain attenuation.

The satellite transmitter 10 continuously transmits satellite beacon signals at a stationary orbital height of about 36,000 km.

The GPS 20 transmits a GPS signal.

The first data collection device 100 measures rainfall attenuation and rainfall intensity to collect rainfall attenuation data and rainfall intensity data (hereinafter referred to as 'rainfall attenuation and rainfall intensity data').

Specifically, when the satellite beacon signal is received from the satellite transmitter 10, the first data collection device 100 measures rainfall attenuation with respect to the received satellite beacon signal to generate rainfall attenuation data. The first data collection device 100 generates rainfall intensity data by measuring rainfall intensity within an effective path length of rainfall attenuation.

When the GPS signal is received from the GPS 20, the first data collecting device 100 extracts time information from the GPS signal and adds the time information to the rainfall attenuation and rainfall intensity data. Specifically, the first data acquisition apparatus 100 converts the GPS signal into 1PPS (Pulse Per Second) to extract time information, and stamps the extracted time information on the front of the rainfall attenuation and rainfall intensity data. Create a time frame.

The first data collecting device 100 checks the time frame, and matches rainfall attenuation data and rainfall intensity data having time information corresponding to each other and stores them in the storage medium.

The first data collection device 100 transmits the matched rainfall attenuation and rainfall intensity data to the data management device 1000. The first data collection device 100 and the data management device 1000 may transmit / receive data at regular intervals (for example, 5 seconds) through an Ethernet communication network.

The data management apparatus 1000 controls the first and second data collection devices 100 and receives and manages rainfall attenuation and rainfall intensity data from the first and second data collection devices 100 and 200. In detail, the data management apparatus 1000 identifies a time frame included in the rainfall attenuation and rainfall intensity data, and classifies the data into regions, minutes, hours, and days according to the time frame. Can be stored in the base.

In addition, the data management apparatus 1000 may generate statistical data by statistically analyzing rainfall attenuation and rainfall intensity data stored in a database for each region and time. In addition, a rainfall damping prediction model can be developed using rainfall attenuation and rainfall intensity data.

Meanwhile, the data management apparatus 1000 may display rainfall attenuation and rainfall intensity data received from the data collection device 100 in real time, and may display the generated statistical data. In addition, the data management apparatus 1000 may monitor operation states of the first and second data collection devices 100 and control operations according to data collection.

2 is a block diagram showing the configuration of a data collection device for collecting rainfall attenuation and rainfall intensity data according to an embodiment of the present invention.

Referring to FIG. 2, the data collection device 100 includes a satellite signal reception module 110, a rainfall attenuation measurement module 120, a GPS signal reception module 130, a rainfall intensity measurement module 140, and a storage medium 150. , A control module 160 and a data transmission / reception module 170. The data collection device 100 may be installed within the effective path length of the rainfall attenuation.

The satellite signal receiving module 110 receives a satellite beacon signal transmitted by the satellite transmitter 10. The satellite signal receiving module 110 may be an antenna for receiving a satellite beacon signal. The satellite signal receiving module 110 may low noise amplify a satellite beacon signal having a weak size transmitted by the satellite transmitter 10 and downconvert the frequency into a signal of an intermediate frequency band.

The rainfall attenuation measurement module 120 measures rainfall attenuation for the frequency down-converted satellite beacon signal to generate rainfall attenuation data. The rainfall attenuation measurement module 120 may measure rainfall attenuation using Equation 1 below.

In Equation 1, A is rainfall attenuation, R is rainfall intensity (mm / hr), a and b are damping coefficients depending on temperature, frequency, polarization, size distribution of raindrop particles, and the like, L _e is the effective path length. Rainfall intensity may be measured by the rainfall intensity measurement module 140.

The GPS signal receiving module 130 receives a GPS signal transmitted by the GPS 20. The GPS signal receiving module 130 may be an active antenna. Commercially available GPS antennas, such as active antennas, receive a C / A code of 1575.42 ± 1.023MHz as a GPS signal and use the correct time information and satellite orbit information to calibrate terrestrial clocks, receive point measurements and speed / direction measurements. Can be done.

The rainfall intensity measurement module 140 measures rainfall intensity to generate rainfall intensity data. The rainfall intensity measurement module 140 measures rainfall intensity using an optical method, and may include a transmission lens, a reception lens, and a control configuration. The rainfall intensity measurement module 140 illuminates an infrared signal for rainfall intensity measurement on a three-dimensional space through a transmission lens, and receives an infrared signal reflected on the three-dimensional space through a reception lens.

The rainfall intensity measurement module 140 compares the infrared signal illuminated by the transmitting lens with the infrared signal received by the receiving lens to calculate a signal change amount, and measures the rainfall intensity corresponding to the signal change amount to obtain the rainfall intensity data. Create

Rainfall intensity measurement module 140 may be installed at least one or more within the effective path length of the rain attenuation, preferably a plurality can be installed.

The control module 160 receives GPS signals, rainfall attenuation data, and rainfall intensity data.

The control module 160 converts the GPS signal into 1PPS (Pulse Per Second) and extracts time information (ToD: Time of Day) from the 1PPS. 1PPS may be NMEA data including time information and location information. The control module 160 generates the time frame by stamping the extracted time information on the front of the rainfall attenuation data and the rainfall intensity data. That is, the control module 160 adds time information extracted at the time when the rainfall attenuation data and the rainfall intensity data are generated to the front of the rainfall attenuation data and the rainfall intensity data in the form of a time frame.

The control module 160 checks the time frames located in front of the rainfall attenuation data and the rainfall intensity data, and matches the rainfall attenuation data and the rainfall intensity data including time information corresponding to each other. The time information may include year, month, day and time information.

The control module 160 checks the time frame to confirm year, month, day, and time information, and matches rainfall attenuation data and rainfall intensity data including year, month, day, and time information corresponding to each other.

The control module 160 stores the rainfall attenuation and rainfall intensity data matched in units of time information in the storage medium 150, and transmits the data transmission / reception module 170 to transmit to the data management apparatus 1000 at regular intervals through the Ethernet communication network. To control. The control module 160 may access TCP / IP of the data management apparatus 1000 that is registered through the Ethernet communication network.

The control module 160 transmits rainfall attenuation and rainfall intensity data in real time to the data management device through the Ethernet communication network, thereby reducing manpower costs and expecting fast data transmission.

The data collection device 100 shown in FIG. 2 may measure rainfall attenuation and rainfall intensity to generate rainfall attenuation and rainfall intensity data, and may transmit them to the data management device in real time and automatically. Therefore, it is possible to reduce the manpower cost spent collecting and transmitting rainfall attenuation and rainfall intensity data.

In addition, the data collection device 100 by installing the rainfall intensity measurement module 140 in different areas within the effective path length of the rain attenuation, it is possible to more accurately measure the rainfall attenuation and rainfall intensity in consideration of the effective path length. .

In addition, the data collection device 100 extracts time information from the GPS signal and adds it to the rainfall attenuation and rainfall intensity data, thereby accurately matching the rainfall attenuation and rainfall intensity data generated at the same time, thereby providing more accurate statistical data and rainfall. Attenuation prediction model can be generated.

Meanwhile, the data collection device 100 shown in FIG. 2 includes a satellite signal receiving module 110, a rainfall attenuation measuring module 120, a GPS signal receiving module 130, a rainfall intensity measuring module 140, and a storage medium 150. ), A control module 160 and a data transmission / reception module 170. However, the data collection device 100 may also be implemented as two devices, each comprising a signal reception and measurement configuration (A) and a data collection configuration (B).

3 is a view showing a rainfall intensity measurement module installed in a plurality of areas according to an embodiment of the present invention.

Referring to FIG. 3, the satellite beacon signal transmitted by the satellite transmitter 10 located at an altitude of about 36,000 km is scattered and attenuated by raindrops while passing through raindrops falling from a cloud floating at an altitude of about 4 km.

When raindrops fall uniformly within the effective path length of the rain attenuation for the satellite beacon signal, the rain attenuation and rainfall intensity may be measured using one rainfall intensity measurement module 141. However, unlike in areas B, C, and D, raindrops do not fall in area A, so rainfall intensity is not measured, but rain attenuation is measured in satellite beacon signals because it is received through raindrops. That is, it is difficult to use the measured rainfall attenuation prediction model as rainfall attenuation is measured in the absence of rainfall intensity. Therefore, the data collection device 100 may include first to fourth rainfall intensity measurement modules 141, 142, 143, and 144 installed at an effective path length of the rainfall attenuation by receiving the satellite beacon signal.

The first rainfall intensity measurement module 141 may be installed in region A of the effective path length of the rainfall attenuation for the satellite beacon signal, and the second rainfall intensity measurement module 142 may be installed in region B. In addition, the third rainfall intensity measurement module 143 may be installed in region C, and the fourth rainfall intensity measurement module 144 may be installed in region D.

The first to fourth rainfall intensity measurement modules 141, 142, 143, and 144 generate rainfall intensity data by measuring rainfall intensity at the same time period according to the control of the control module 160. The rainfall intensity data generated as described above may include region information of an area in which the first to fourth rainfall intensity measurement modules 141, 142, 143, and 144 are installed.

The control module 160 may check time information and region information included in the plurality of rainfall intensity data, and generate statistical data by classifying the type of rainfall and the rainfall intensity according to time and region.

In addition, although the first rainfall intensity measurement module 141 installed in the area A does not fall, even if installed within the effective path length of the rain attenuation, the second to fourth rainfall intensity measurement module (142, 143, 144) Average rainfall intensity data may be generated with respect to the rainfall intensity data generated at. The rainfall attenuation measurement module 120 may apply the average rainfall intensity data to Equation 1 to measure rainfall attenuation.

4 is a flowchart illustrating a method of collecting and managing rainfall attenuation and rainfall intensity data in a satellite communication system according to an embodiment of the present invention.

Referring to FIG. 4, the data collection device 100 receives a satellite beacon signal from the satellite transmitter 10 (step 410). The data collecting device 100 receives the GPS signal from the GPS and extracts time information from the GPS signal (step 420). The data collection device 100 may receive the satellite beacon signal and the GPS signal at regular time periods.

The data collection device 100 measures rainfall attenuation with respect to the received satellite beacon signal to generate rainfall attenuation data (step 430).

The data collection device 100 generates rainfall intensity data by measuring rainfall intensity in at least one region included in the effective path length of the rainfall attenuation (S440). The rainfall intensity measurement module 140 for measuring the rainfall intensity may be installed in at least one region included in the effective path length, or may be installed in a plurality of regions. The rainfall intensity measurement module 140 may measure the rainfall intensity using a transmitting lens and a receiving lens. In detail, the rainfall intensity measurement module 140 illuminates an infrared signal on a three-dimensional space through a transmission lens, and calculates a signal change amount of the infrared signal received through the reception lens. The rainfall intensity measurement module 140 generates rainfall intensity data by measuring rainfall intensity corresponding to the calculated signal conversion amount.

The data collection device 100 adds time information extracted from the GPS signal to the rainfall attenuation and rainfall intensity data (step 450).

The data collection device 100 matches the rainfall attenuation data to which the time information is added and the rainfall intensity data in units of time information corresponding to each other (step 460).

The data collection device 100 transmits and manages the rainfall attenuation data and the rainfall intensity data matched in units of time information to the data management apparatus 1000 (step 470).

The method illustrated in FIG. 4 can collect rainfall attenuation and rainfall intensity data close to actual situations, and can use these data to generate statistical data and rainfall attenuation prediction models more accurately.

Embodiments according to the present invention can be implemented in the form of program instructions that can be executed by various computer means can be recorded on a computer readable medium. Such computer-readable media may include, alone or in combination with the program instructions, data files, data structures, and the like. The program instructions recorded on the recording medium may be those specially designed and constructed for the present invention, or may be known and available to those skilled in computer software. Examples of the computer-readable recording medium include magnetic media such as a hard disk, a floppy disk, and a magnetic tape; optical media such as CD-ROM and DVD; magnetic recording media such as a floppy disk; Magneto-optical media, and hardware devices specifically configured to store and execute program instructions such as ROM, RAM, flash memory, and the like. Examples of program instructions include not only machine code generated by a compiler, but also high-level language code that can be executed by a computer using an interpreter or the like. The hardware device described above may be configured to operate as one or more software modules to perform the operations of the present invention, and vice versa.

As described above, although the present invention has been described with reference to the limited embodiments and the drawings, the present invention is not limited to the above embodiments, and those skilled in the art to which the present invention pertains various modifications and variations from such descriptions. This is possible. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined not only by the claims below but also by the equivalents of the claims.

100: data acquisition device 110: satellite signal receiving module
120: rainfall attenuation measurement module 130: GPS signal receiving module
140: rainfall intensity measurement module 150: storage medium
160: control module 170: data transmission and reception module
1000: data management device

Claims (4)

In a system for collecting and managing rainfall attenuation data and rainfall intensity data in a satellite communication system,
A satellite transmitter for transmitting satellite beacon signals;
A GPS for transmitting a Global Positioning System (GPS) signal;
When a satellite beacon signal is received from the satellite transmitter, rainfall attenuation data is generated for the received satellite beacon signal, rainfall intensity data is generated within an effective path length of the rainfall attenuation, and time information is obtained from the GPS signal. At least one data collection device that is extracted and added to the rainfall attenuation data and the rainfall intensity data; And
A data management device configured to receive and manage the rainfall attenuation data and the rainfall intensity data to which the time information is added;
A system for collecting and managing rainfall attenuation and rainfall intensity data, including.
The method of claim 1,
The at least one data collection device,
A satellite signal receiving module which receives the satellite beacon signal transmitted by the satellite transmitter and down-converts the satellite beacon signal into a signal of an intermediate frequency band;
A GPS signal receiving module configured to receive the GPS signal transmitted by the global positioning system (GPS);
A rainfall attenuation measurement module for measuring rainfall attenuation of the satellite beacon signal converted to the intermediate frequency band to generate the rainfall attenuation data;
A rainfall intensity measurement module installed within an effective path length of the rainfall attenuation and measuring rainfall intensity to generate the rainfall intensity data;
The control module extracts time information from the GPS signal and adds it to the rainfall attenuation data and the rainfall intensity data, and matches the rainfall attenuation data and the rainfall intensity data in corresponding time information units and stores them in a storage medium.
A data transmission / reception module for transmitting the rainfall attenuation data and the rainfall intensity data matched with the time information unit to the data management device according to the control of the control module
A system for collecting and managing rainfall attenuation and rainfall intensity data, including.
The method of claim 2,
The control module,
The GPS signal is converted into 1PPS (Pulse Per Second) to extract time information from the 1PPS, and the time information is stamped on the front of the rainfall attenuation data and the rainfall intensity data to generate a time frame. A system for collecting and managing rainfall attenuation and rainfall intensity data.
The method of claim 2,
The control module,
And collecting and managing rainfall attenuation data and rainfall intensity data for controlling the data transmission / reception module to transmit the rainfall attenuation data and the rainfall intensity data matched with the time information unit to the data management apparatus through an Ethernet communication network.

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